• Unified ML model accurately predicts pellet quality for raw and pretreated biomass. • Thermo-mechanical process rules act as key determinants of pellet quality. • Mechanistic insights reveal chemistry-driven and pretreatment-specific limits. • Unified model reduces computation by 25% compared to pathway-specific models. • Graphical user interface enables feedstock-agnostic prediction of pellet quality. Biomass pellets offer a renewable pathway for decarbonising industrial energy and metallurgical processes, yet inconsistent quality limits widespread adoption. This study presents a unified interpretable machine learning framework that predicts pellet density and mechanical strength across raw, hydrochar, and torrefied biomass feedstocks. A literature-derived dataset spanning feedstock properties, pretreatment conditions, and densification parameters was compiled to capture heterogeneity in pelletisation systems. Eight algorithms were benchmarked using Bayesian optimisation and 5-fold cross-validation, achieving R 2 > 0.85 with root-mean-square errors within experimental uncertainty. Interpretability analyses revealed critical nonlinear interactions among binder content, feedstock composition, and thermo-mechanical conditions that influence densification performance. The unified framework matched experimental-grade pellet specifications (∼1.2 g cm− 3 ; 6–7 MPa) while reducing computational cost by approximately 25% compared to pathway-specific models. The framework provides generalisable thermo-mechanical design principles and is deployed through a graphical interface, enabling users to predict pellet quality based on compositional and process inputs.
Khan et al. (Fri,) studied this question.